A structure for grounding an extreme ultraviolet mask (EUV mask) is provided to discharge the EUV mask during the inspection by an electron beam inspection tool. The structure for grounding an EUV mask includes at least one grounding pin to contact conductive areas on the EUV mask, wherein the EUV mask may have further conductive layer on sidewalls or/and back side. The inspection quality of the EUV mask is enhanced by using the electron beam inspection system because the accumulated charging on the EUV mask is grounded. The reflective surface of the EUV mask on a continuously moving stage is scanned by using the electron beam simultaneously. The moving direction of the stage is perpendicular to the scanning direction of the electron beam.

A system for zapping a wafer, the system may include a pulse generation unit that is configured to generate (a) first zapping pulses for causing a breakdown in a first location of a backside insulating layer of a wafer, and (b) second zapping pulses for causing a breakdown in a second location of the backside insulating layer of the wafer; a first conductive interface that is configured to convey the first zapping pulses to the first location, while contacting the first location; a second conductive interface that is configured to convey the second zapping pulses to the second location, while contacting the second location; and wherein the first location differs from the second location.

A system for zapping a wafer, the system includes a pulse generator; a sensor; a first conductive interface; a second conductive interface; a controller; wherein the pulse generator is configured to generate zapping pulses; wherein the first conductive interface is configured to provide the zapping pulses to a first location of a backside insulating layer of a wafer; wherein the sensor is configured to monitor a coupling between the first conductive interface and the second conductive interface to provide a monitoring result; wherein the monitoring occurs while the second conductive interface contacts a second location of the backside insulating layer; and wherein the controller is configured to control a generation of the zapping pulses in response to the monitoring result.

One embodiment relates to an apparatus for virtual grounding of a target substrate in a charged-particle beam apparatus. A primary gun generates charged particles for a process beam that is focused on a frontside surface of the target substrate, and the target substrate is held by a stage. An electrostatic voltmeter measures a voltage potential of the target substrate, and a charge-control gun impinges a beam of charged particles to the target substrate. A feedback control loop is used to control the flood gun depending on the voltage potential measured by the electrostatic voltmeter. Other embodiments, aspects and features are also disclosed.

A member for semiconductor manufacturing apparatus includes a ceramic plate that has an upper surface including a reference surface on which multiple small projections for supporting a wafer are provided and that contains an electrostatic electrode; a plug arrangement hole that is provided in the ceramic plate; an electrostatic electrode opening portion that is provided at a position in the electrostatic electrode through which the plug arrangement hole extends; a cooling plate that is provided on a lower surface of the ceramic plate; a gas hole that extends through the cooling plate and that is in communication with the plug arrangement hole; a plug that is arranged in the plug arrangement hole and that includes a gas flow path; and a raised portion that surrounds the gas flow path and that has a top surface higher than the reference surface and lower than top surfaces of the small projections.

The present disclosure provides a substrate processing apparatus. The substrate processing apparatus includes a chamber defining a processing space, a gas supply unit supplying a process gas to the processing space, and a support unit supporting a substrate in the processing space, wherein the support unit includes a chuck supporting the substrate, a power applying RF power to the chuck, and an ionization path through which static electricity generated in the chuck is removed.

A structure for grounding an extreme ultraviolet mask (EUV mask) is provided to discharge the EUV mask during the inspection by an electron beam inspection tool. The structure for grounding an EUV mask includes at least one grounding pin to contact conductive areas on the EUV mask, wherein the EUV mask may have further conductive layer on sidewalls or/and back side. The inspection quality of the EUV mask is enhanced by using the electron beam inspection system because the accumulated charging on the EUV mask is grounded. The reflective surface of the EUV mask on a continuously moving stage is scanned by using the electron beam simultaneously. The moving direction of the stage is perpendicular to the scanning direction of the electron beam.

A structure for discharging an extreme ultraviolet mask (EUV mask) is provided to discharge the EUV mask during the inspection by an electron beam inspection tool. The structure for discharging an EUV mask includes at least one grounding pin to contact conductive areas on the EUV mask, wherein the EUV mask may have further conductive layer on sidewalls or/and bottom. The inspection quality of the EUV mask is enhanced by using the electron beam inspection system because the accumulated charging on the EUU mask is grounded.

A method for plasma processing includes biasing a substrate by ramping a sheath voltage during a first phase of a plasma process and removing sidewall charge buildup on a feature of the substrate in an absence of substrate biasing during a second phase of the plasma process.

A structure for discharging an extreme ultraviolet mask (EUV mask) is provided to discharge the EUV mask during the inspection by an electron beam inspection tool. The structure for discharging an EUV mask includes at least one grounding pin to contact conductive areas on the EUV mask, wherein the EUV mask may have further conductive layer on sidewalls or/and bottom. The inspection quality of the EUV mask is enhanced by using the electron beam inspection system because the accumulated charging on the EUU mask is grounded.